EP1220047A2

EP1220047A2 - Sheet feeding device and image forming apparatus using the sheet feeding device

Info

Publication number: EP1220047A2
Application number: EP01310886A
Authority: EP
Inventors: Katsuhiko Miki
Original assignee: Ricoh Co Ltd
Current assignee: Ricoh Co Ltd
Priority date: 2000-12-28
Filing date: 2001-12-24
Publication date: 2002-07-03
Anticipated expiration: 2021-12-24
Also published as: JP3782721B2; US20020096817A1; EP1220047A3; JP2002255377A; US6601843B2; EP1220047B1

Abstract

A sheet feeding device includes a sheet tray configured to accommodate stacked sheets, and a feeding unit (30) configured to feed the stacked sheets in the sheet tray one by one. The sheet feeding unit includes a feeding roller (21) configured to be driven to rotate in a sheet feeding direction in which each of the stacked sheets is fed, and a separation roller (22) configured to be pressed against the feeding roller when feeding each of the stacked sheets and to be driven to rotate, via a torque limiter, in a direction opposite the sheet feeding direction. The separation roller is rotated by rotation of the feeding roller in the sheet feeding direction when a single sheet of the stacked sheets is sandwiched between the feeding roller and the separation roller. The sheet feeding unit further includes a conveying member (24) arranged downstream of the feeding roller in the sheet feeding direction, a driving source for driving the feeding roller, the separation roller, and the conveying member, and a driving force transmission mechanism configured to transmit a driving force of the driving source to each of the feeding roller, the separation roller and the conveying member such that the separation roller and the conveying member are driven in conjunction with each other.

Description

The present invention relates to a sheet feeding device for use in image forming apparatuses, such as copying machines, printers, facsimile apparatuses, printing apparatuses, etc., and an image forming apparatus using the sheet feeding device.
In sheet feeding devices for image forming apparatuses, various methods have been proposed for separating stacked sheets so as to be fed one by one. A friction separation method is one of well known methods. A sheet feeding device using a friction separation method generally includes a feeding roller which rotates in a sheet feeding direction, a separation roller which is pressed against the feeding roller and which is driven, via a torque limiter, to rotate in a direction opposite the sheet feeding direction, and a conveying roller arranged downstream of the feeding roller and the separation roller in the sheet feeding direction. When one sheet is sandwiched between the feeding roller and the separation roller, the separation roller is rotated by rotation of the feeding roller via the torque limiter, and when two sheets or more are sandwiched between the feeding roller and the separation roller, the sheets are separated from each other so as to be fed one by one because the separation roller is rotated in the opposite direction relative to the sheet feeding direction.
In a sheet feeding device using a friction separation method, driving of a feeding roller, a separation roller and a conveying roller with individual driving sources is not desirable from the viewpoint of cost. Therefore, it has been often practiced to drive a feeding roller, a separation roller and a conveying roller with a single driving source. Each of the rollers is connected with or disconnected from the single driving source using, for example, an electromagnetic clutch and a solenoid. However, in an electric clutch, there are possibilities that an inferior operation of the sheet feeding device may be caused, depending upon the amount of driving load for the connection and/or the disconnection, by variation in the periods of connection and/or disconnection of the driving source with or from each of the rollers with the electric clutch or by slippage in the clutch. This may consequently adversely influence the sheet conveying property of the sheet feeding device to cause sheet jamming in the sheet feeding device.
The above-described disadvantage in using an electric clutch in a sheet feeding device is addressed in Japanese Patent Laid-open Publication No. 8-59000. In JP No. 8-59000, a plurality of sheet feeding devices are provided in multiple-stages, and each of the sheet feeding devices includes an individual sheet feeding unit. In the sheet feeding unit, a feeding roller, a separation roller, and a conveying roller are driven, using a mechanical clutch such as a one-way clutch, by switching rotation of a single reversible motor between forward and reverse directions. Specifically, the feeding roller, the separation roller, and the conveying roller are driven when the motor rotates in the forward direction, and only the conveying roller is driven at a high speed when the motor rotates in the reverse direction. In the sheet feeding device of JP No. 8-59000, because driving of the separation roller is stopped together with the feeding roller when rotation of the motor is reversed, if a subsequent sheet is stuck to a part of a sheet being fed, due to static electricity, etc., the subsequent sheet might be fed together with the sheet being fed, resulting in so-called double feeding of sheets.
The present invention has been made in view of the above-discussed and other problems and addresses the above-discussed and other problems.
Preferred embodiments of the present invention provide a novel sheet feeding device and a novel image forming apparatus, that include a driving force transmitting mechanism not using an electric clutch and that avoid double feeding of sheets.
According to a preferred embodiment of the present invention, a sheet feeding device includes a sheet tray configured to accommodate stacked sheets, and a feeding unit configured to feed the stacked sheets in the sheet tray one by one. The sheet feeding unit includes a feeding roller configured to be driven to rotate in a sheet feeding direction in which each of the stacked sheets is fed, and a separation roller configured to be pressed against the feeding roller when feeding each of the sheets and to be driven to rotate, via a torque limiter, in a direction opposite the sheet feeding direction. The separation roller is rotated by rotation of the feeding roller in the sheet feeding direction when a single sheet of the stacked sheets is sandwiched between the feeding roller and the separation roller. The sheet feeding unit further includes a conveying member arranged downstream of the feeding roller in the sheet feeding direction, a driving source for driving the feeding roller, the separation roller, and the conveying member, and a driving force transmission mechanism configured to transmit a driving force of the driving source to each of the feeding roller, the separation roller and the conveying member such that the separation roller and the conveying member are driven in conjunction with each other.
In the above-described sheet feeding device, the driving source may include a reversible motor configured to be switched between being driven to rotate in first and second directions. In this case, the driving transmission mechanism may be configured to transmit the driving force of the motor such that the feeding roller, the separation roller, and the conveying member are driven when the driving source is driven to rotate in the first direction, and such that the feeding roller is not driven and the separation roller and the conveying member are driven in conjunction with each other when the driving source is driven to rotate in the second direction.
Further, the separation roller and the conveying member may be configured to be continuously driven in conjunction with each other by the driving source from when each sheet starts to be fed by the feeding roller until the sheet passes the conveying member.
Furthermore, the driving source may be switched from being driven to rotate in the first direction to being driven to rotate in the second direction while the sheet is being sandwiched between the feeding roller and the separation roller.
Still furthermore, the driving force transmission mechanism may include driving force transmission members and mechanical one-way clutches, and the driving force transmission members may include gears and a belt. In this case, when the driving source is driven to rotate in the first direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via the belt and the gears, and when the driving source is driven to rotate in the second direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via the belt. Alternatively, the driving force transmission members may include a series of gears. In this case, when the driving source is driven to rotate in the first direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via a first portion of the series of gears, and when the driving source is driven to rotate in the second direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via a second portion of the series of gears, the first portion of the series of gears is greater in number than the second portion of the series of gears by an odd number.
Further, the driving force transmission mechanism may include a first rotation transmission route configured to transmit the driving force of the driving source when the driving source is driven to rotate in the first direction and a second rotation transmission route configured to transmit the driving force of the driving source when the driving source is driven to rotate in the second direction.
In this case, the driving force transmission mechanism may includes a belt and gears, and the first rotation transmission route may be configured to transmit the driving force of the driving source to the feeding roller via the belt and then from the feeding roller to the separation roller via the gears, and the second rotation transmission route may be configured to transmit the driving force of the driving source to the separation roller via the belt. Alternatively, the driving force transmission mechanism may include a series of gears. In this case, the forward rotation transmission route may be configured to transmit the driving force of the driving source to the separation roller via a first portion of the series of gears and the second rotation transmission route may be configured to transmit the driving force of the driving source to the separation roller via a second portion of the series of gears , and the first portion of the series of gears may be greater in number than the second portion of the series of gears by an odd number.
Furthermore, in the above-described sheet feeding device, the sheet feeding unit may be detachable from the sheet feeding device.
According to another preferred embodiment of the present invention, an image forming apparatus includes an image forming unit configured to form a toner image on a photoconductor, and a plurality of sheet feeding devices . Each of the sheet feeding devices includes a sheet tray configured to accommodate stacked sheets and a sheet feeding unit configured to feed the stacked sheets in the sheet tray one by one toward the image forming unit so that the toner image is transferred onto each sheet at the image forming unit. The sheet feeding unit includes a feeding roller configured to be driven to rotate in a sheet feeding direction in which each of the stacked sheets is fed, and a separation roller configured to be pressed against the feeding roller when feeding each of the stacked sheets and to be driven to rotate, via a torque limiter, in a direction opposite the sheet feeding direction. The separation roller is rotated by rotation of the feeding roller in the sheet feeding direction when a single sheet of the stacked sheets is sandwiched between the feeding roller and the separation roller. The sheet feeding unit further includes a conveying member arranged downstream of the feeding roller in the sheet feeding direction, a driving source for driving the feeding roller, the separation roller, and the conveying member, and a driving force transmission mechanism configured to transmit a driving force of the driving source to each of the feeding roller, the separation roller and the conveying member such that the separation roller and the conveying member are driven in conjunction with each other.
In the above-described image forming apparatus, the driving source of each sheet feeding unit of the plurality of sheet feeding devices may include a reversible motor configured to be switched between being driven to rotate in first and second directions.
Further, the driving transmission mechanism of each sheet feeding unit of the plurality of sheet feeding devices may be configured to transmit the driving force of the motor such that the feeding roller, the separation roller, and the conveying member are driven when the driving source is driven to rotate in the first direction, and such that the feeding roller is not driven and the separation roller and the conveying member are driven in conjunction with each other when the driving source is driven to rotate in the second direction.
Furthermore, the separation roller and the conveying member of each sheet feeding unit of the plurality of sheet feeding devices may be configured to be continuously driven in conjunction with each other by the driving source from when each sheet starts to be fed by the feeding roller until the sheet passes the conveying roller.
Still furthermore, the driving source may be switched from being driven to rotate in the first direction to being driven to rotate in the second direction while the sheet is being sandwiched between the feeding roller and the separation roller.
Further, the driving force transmission mechanism of each sheet feeding unit of the plurality of sheet feeding devices may include driving force transmission members and mechanical one-way clutches, and the driving force transmission members may include gears and a belt. In this case, when the driving source is driven to rotate in the first direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via the belt and the gears, and when the driving source is driven to rotate in the second direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via the belt. Alternatively, the driving force transmission members may include a series of gears. In this case, when the driving source is driven to rotate in the first direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via a first portion of the series of gears, and when the driving source is driven to rotate in the second direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via a second portion of the series of gears , and the first portion of the series of gears may be greater in number than the second portion of the series of gears by an odd number.
Further, the sheet feeding unit of each of the plurality of sheet feeding devices may be detachable from the sheet feeding device.
Furthermore, in the above-described image forming apparatuses, the plurality of sheet feeding devices may be arranged in multiple stages in a vertical direction in parallel with each other. In this case, the sheet feeding units of the plurality of sheet feeding devices are individually driven such that each sheet fed from one of the plurality of sheet feeding devices is fed toward the image forming unit via the conveying member of each of other sheet feeding devices of the plurality of sheet feeding devices located above the sheet feeding device from which the sheet has been fed. Further, the sheet feeding units of any neighboring sheet feeding devices of the plurality of sheet feeding devices may be connected with each other such that the driving force of the driving source of the feeding unit of the sheet feeding device of the neighboring sheet feeding devices, located at a low side, is not transmitted to the feeding unit of the sheet feeding device of the neighboring feeding devices, located at an upper side, and the driving force of the driving source of the feeding unit of the sheet feeding device of the neighboring sheet feeding devices, located at the upper side, is transmitted to the sheet feeding unit of the sheet feeding device of the neighboring sheet feeding devices, located at the lower side. In this case, further, the separation roller and the conveying member of the feeding unit of an uppermost sheet feeding device of the plurality of sheet feeding devices and the separation roller and the conveying member of the feeding unit of the sheet feeding device of the plurality of sheet feeding devices, feeding the sheet, may be driven in conjunction with each other, respectively, and the separation roller and the conveying member of each of the sheet feeding units of other sheet feeding devices of the plurality of sheet feeding devices, not feeding the sheet, may not be driven in conjunction with each other and only the conveying member may be driven.
In the above-described image forming apparatuses, the driving source of the sheet feeding unit of the sheet feeding device of the plurality of sheet feeding devices, feeding the sheet, may be driven by a predetermined power. In this case, the driving source of the sheet feeding unit of each of other sheet feeding devices located above the sheet feeding device feeding the sheet is driven at a power lower than the predetermined power. Further, the driving source of the sheet feeding unit of each of the other sheet feeding devices located below the sheet feeding device, feeding the sheet, may not be driven.
In the above-described image forming apparatuses, each of the sheet feeding devices may include a contact/separation device configured to bring the separation roller into contact with and to separate the separation roller from the feeding roller. The contact/separation device is configured to separate the separation roller from the feeding roller except when the sheet feeding device feeds each of the stacked sheets.
A more complete appreciation of the present invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in conjunction with accompanying drawings, wherein:
Fig. 1 is a schematic drawing of an image forming apparatus including a plurality of sheet feeding devices according to a preferred embodiment of the present invention;
Fig. 2 is an enlarged schematic drawing of a sheet tray and a sheet feeding unit of each of the sheet feeding devices;
Fig. 3 is a schematic drawing of the sheet feeding unit;
Fig. 4 is a front view of the sheet feeding unit;
Fig. 5 is a schematic drawing illustrating an exemplary construction of the sheet feeding unit for detachably mounting the sheet feeding unit to a main body of the sheet feeding device;
Fig. 6 is schematic drawing for explaining a contacting/separating operation of a separation roller relative to a feeding roller in the sheet feeding device;
Fig. 7 is a perspective drawing illustrating an exemplary construction of a contact/separation device of the sheet feeding device to move the separation roller to contact and separate from the feeding roller;
Fig. 8 is a schematic drawing for explaining an operation of the contact/separation device;
Fig. 9 is a table indicating a driving state of each sheet feeding unit of multiple-staged sheet feeding devices when each of the sheet feeding devices is selected for sheet feeding;
Fig. 10 is a schematic drawing of a sheet feeding unit of the sheet feeding device, according to another preferred embodiment of the present invention;
Fig. 11 is a front view of four sheet feeding devices arranged in multiple-stages in a vertical direction, each including the sheet feeding unit of Fi. 10;
Fig. 12 is a table indicating a driving status of each sheet feeding unit of the multiple-staged sheet feeding devices of Fig. 11; and
Fig. 13 is a schematic drawing of a sheet feeding unit of the sheet feeding device according to still another preferred embodiment of the present invention, which drives a feeding roller and a separation roller via a series of gears.
Referring now to the drawings, wherein like reference numerals designate identical or corresponding parts throughout the several views, preferred embodiments of the present invention are described.
Fig. 1 is a schematic drawing of an image forming apparatus including a plurality of sheet feeding devices according to a preferred embodiment of the present invention. In Fig. 1, numeral 1 denotes a main body of the image forming apparatus, in which an image forming part 2 is provided. The image forming part 2 includes a photoconductor drum 3 as an image bearing member. The image forming part 2 performs image formation according to a known electrophotography. A sheet feeding part 10 including multiple-staged sheet feeding devices, four sheet feeding devices 11, 12, 13 and 14 in this embodiment, is arranged below the image forming part 2, to convey a sheet therefrom toward the image forming part 2. Further, a manual sheet feeding device 4, and a sheet reversing unit 5 for forming images on both sides of a sheet are provided in the main body 1 of the apparatus.
In the above-described image forming apparatus, a sheet fed out from the sheet feeding part 10 or fed from the manual sheet feeding device 4 is conveyed to a registration roller 6 of the image forming part 2, and is then conveyed to a transfer part of the image forming part 2 by the registration roller 6 in synchronism with a timing that a toner image formed on a surface of the photoconductor drum 3 is moved to the transfer part. A transferring belt 7 is provided at the transfer part. The toner image is transferred onto the sheet conveyed to the transfer part by the transferring belt 7, and at the same time the sheet is conveyed by movement of the transferring belt 7 to a fixing device 8. The toner image is fixed onto the sheet at the fixing device 8, for example, by an operation of heat and pressure. The sheet is then selectively conveyed to a sheet discharging part 9 or to the reversing unit 5.
Fig. 2 is an enlarged schematic drawing illustrating a sheet tray accommodating stacked sheets and a sheet feeding unit of each of the sheet feeding devices 11, 12, 13 and 14 of the sheet feeding part 10. Fig. 3 is a schematic drawing illustrating a driving force transmission mechanism of the sheet feeding unit.
Each of the sheet feeding devices 11, 12, 13 and 14 employs a friction separation method, and includes, as illustrated in Figs. 1 and 2, a sheet tray 20 configured to accommodate stacked sheets, and a sheet feeding unit 30 configured to feed the stacked sheets one by one. The sheet feeding unit 30 includes, as illustrated in Fig. 2, a feeding roller 21 configured to be driven to rotate in a sheet feeding direction in which a sheet P is fed, a separation roller 22 configured to be pressed against the feeding roller 21 when feeding the sheet P and to be driven via a torque limiter (not shown in Fig. 2) to rotate in a sheet returning direction in which the sheet P is returned, a pick-up roller 23 arranged on the stacked sheets accommodated in the sheet tray 20 and configured to rotate in the sheet feeding direction to feed the sheet P from the sheet tray 20, and a conveying roller 24 serving as a conveying member for further conveying the sheet P fed by the feeding roller 21. In each of the sheet feeding devices 11, 12, 13, and 14, upon start of a sheet feeding operation, the pick-up roller 23, to which a driving force of the feeding roller 21 is transmitted, first feeds an uppermost sheet P of the stacked sheets in the sheet tray 20 in a direction indicated by arrow A (Fig. 2). The fed sheet P is then sandwiched between the feeding roller 21 and the separation roller 22 at a nip thereof. At this time, when the fed sheet P is single, the separation roller 22 is rotated by a conveying force of the feeding roller 21, so that the sheet P is fed in the sheet feeding direction. The sheet P is further conveyed by the conveying roller 24 to the registration roller 6. When plural sheets P are fed between the feeding roller 21 and the separation roller 22, because a predetermined torque is given to the separation roller 22 in the sheet returning direction, the separation roller 22 rotates in the sheet returning direction. Thereby, the sheet P contacting the separation roller 22 is returned, and only the uppermost sheet P of the plural sheets P is fed by the feeding roller 21. In Fig. 2, numerals 27 and 28 denote driven conveying rollers contacting the conveying roller 24.
The sheet feeding unit 30 of each of the sheet feeding deices 11, 12, 13 and 14 includes, as illustrated in Fig. 3, a motor 31 serving as a driving source. In the embodiment, a stepping motor which is rotatable in two directions, first and second directions, is used for the motor 31. A driving force of the motor 31 is transmitted via a driving force transmission mechanism (described below) to the feeding roller 21, the separation roller 22, and the conveying roller 24. The feeding roller 21, the separation roller 22, and the conveying roller 24 are supported by a frame 29 (Fig. 2) of the sheet feeding unit 30.
Now, referring to Fig. 3, the driving force transmission mechanism of the sheet feeding unit 30 is described. A timing pulley 35 is provided to an output axis 32 of the motor 31, a timing pulley 36 having a gear 39 is provided to a driving axis 33 of the feeding roller 21, a timing pulley 37 is provided to a driving axis 34 of the separation roller 22, and a timing belt 38 is spanned around the timing pulleys 35, 36 and 37. The timing belt 38 spanned around the timing pulleys 35, 36 and 37 is formed, as illustrated in Fig. 4, in a triangle when viewed from the front of the image forming apparatus.
A driving force of the motor 31 is conveyed from the timing pulley 35, via the timing belt 38 and the timing pulley 36 having a gear 39, to the driving axis 33 of the feeding roller 21, and from the timing pulley 35, via the timing belt 38 and the timing pulley 37, to the driving axis 34 of the separation roller 22. In Fig. 3, numeral 25 denotes a torque limiter.
One- way clutches 36a and 37a are provided to the timing pulley 36 having the gear 39 and to the timing pulley 37, respectively. Further, a gear 40 engaging with the gear 39 of the pulley 36 is provided to the driving axis 34 of the separation roller 22, and a one-way clutch 40a is also provided to the gear 40. The one-way clutch 36a is configured to be locked relative to a direction in which the timing belt 38 is rotated when the motor 31 is driven to rotate in the first direction (hereinafter, the forward direction), so that a driving force of the motor 31 is transmitted. In this rotation direction of the timing bell 38, the one-way clutch 37a does not transmit the driving force of the motor 31. Further, the one-way clutch 40a transmits the driving force of the motor 31 when the driving axis 33 of the feeding roller 21 is rotated by driving of the motor 31 to rotate in the forward direction. Accordingly, when the motor 31 is driven to rotate in the forward direction, the driving axis 33 of the feeding roller 21 is driven to rotate via the output axis 32, the timing belt 38, and the pulley 36 having the gear 39. Further, the driving force of the motor 31 is transmitted to the driving axis 34 of the separation roller 22 via the pulley 36 having the gear 39 and the gear 40. When the motor 31 is driven to rotate in the forward direction, the one-way clutch 37a is idle, and therefore the driving force of the motor 31 is not transmitted to the driving axis 34 of the separation roller 22 via the timing pulley 37. Accordingly, when the motor 31 is driven to rotate in the forward direction, both the feeding roller 21 and the separation roller 22 are driven to rotate. A route in which the driving force of the motor 31 is transmitted to the driving axis 34 of the separation roller 22 via the timing belt 38, the timing pulley 36 having the gear 39 and the gear 40 is a first driving force transmission route according to the embodiment.
When the motor 31 is driven to rotate in the second direction (hereinafter, the reverse direction), in the direction in which the timing belt 38 moves at this time, the one-way clutch 36a does not transmit a driving force of the motor 31, so that the driving axis 33 of the feeding roller 21 is not driven to rotate. On the other hand, because the one-way clutch 37a of the driving axis 34 of the separation roller 22 transmits the driving force of the motor 31 at that time, the driving force of the motor 31 is transmitted via the timing belt 38 and the timing pulley 37 to the driving axis 34 of the separation roller 22, so that the separation roller 22 is driven to rotate. At this time, because the one-way clutch 40a does not transmit a driving force of the driving axis 34, the gear 40 does not rotate, so that a rotation of the driving axis 34 of the separation roller 22 is never transmitted to the driving axis 33 of the feeding roller 21 via the gear 40 and the timing pulley 36 having the gear 39. Here, a route in which a driving force of the motor 31 is transmitted to the driving axis 34 of the separation roller 22 via the timing belt 38 and the timing pulley 37 is a second driving force transmission route according to the embodiment.
Thus, the driving axis 33 of the feeding roller 21 is configured to be driven to rotate only when the motor 31 rotates in the forward direction, and the driving axis 34 of the separation roller 22 is configured to be driven to rotate when the motor 31 rotates in either of the forward and reverse directions. Further, a gear 41 is provided to the driving axis 34 of the separation roller 22, and the gear 41 engages with a gear 42 provided to a driven axis 43 to which the separation roller 22 is mounted. By configuring the separation roller 22 as described above, i.e., by providing the separation roller 22 to the driven axis 43 instead of the driving axis 34 and connecting the driven axis 43 and the driving axis 34 with the gears 41 and 42, separation pressure of the separation roller 22 relative to the feeding roller 21 can be adjusted by adjusting gear surface pressures of the gears 41 and 42.
A timing pulley 44 is provided to the driving axis 34 of the separation roller 22, and a gear 48 which engages with a gear 47 of a timing pulley 46 having a gear is provided to a roller axis 45 of the conveying roller 24. Further, a timing belt 49 is spanned around the timing pulley 44 and the timing pulley 46 having a gear. Thus, the conveying roller 24 rotates when the driving axis 34 of the separation roller 22 is driven to rotate. Accordingly, when the separation roller 22 is driven, the conveying roller 24 is driven to rotate.
In each of the sheet feeding devices 11, 12, 13 and 14, each having the sheet feeding unit 30 configured as described above, when a sheet feeding instruction is given, the motor 31 is rotated in the forward direction, and thereby the feeding roller 21, the separation roller 22, and the conveying roller 24 are driven to rotate in predetermined directions, respectively. Further, the pick-up roller 23, connected with the driving axis 33 of the feeding roller 21 via an idle gear (not shown), is driven to rotate in a predetermined direction with the forward rotation of the motor 31.
After a sheet fed by the pick-up roller 23 is separated from other sheets by the feeding roller 21 and the separation roller 22, the sheet is conveyed by the conveying roller 24. Once a sheet has been fed to the conveying roller 24, the sheet can be conveyed, without driving of the feeding roller 21 to rotate, by rotation of the conveying roller 24. Driving of the feeding roller 21 should preferably turned off while a sheet to be fed is being sandwiched by the feeding roller 21 and the separation roller 22. Therefore, in the embodiment, as illustrated in Fig. 2, a sensor 26 is arranged downstream of the conveying roller 24 in the sheet conveying direction and in the vicinity thereof, so that when the sensor 26 detects a leading edge of the sheet, rotation direction of the motor 31 is switched from the forward direction to the reverse direction.
When the motor 31 is driven to rotate in the reverse direction, as described above, the feeding roller 21 is not driven to rotate, but the separation roller 22 and the conveying roller 24 continue to be driven until the sheet passes the conveying roller 24. Thus, the separation roller 22 and the conveying roller 24 are driven to rotate in conjunction with each other during a sheet feeding operation, so that even if a subsequent sheet is stuck to a part of the sheet to be fed by static electricity, etc., the subsequent sheet is returned by the separation roller 22, thus preventing double feeding of sheets. The driving of the separation roller 22 and the conveying roller 24 in conjunction with each other can be performed by using individual driving sources (motors). However, it is advantageous to perform the driving of the separation roller 22 and the conveying roller 24 with a single driving source as in the above-described embodiment from the standpoints of costs and space saving. Further, the one-way clutch 48a is provided to the gear 48, so that when the gear 48 rotates, rotation of the gear 48 is transmitted to the axis 45 of the conveying roller 24. Accordingly, even if the conveying roller 24 rotates via a sheet being is conveyed, the rotation of the conveying roller 24 is not transmitted to the gear 48.
The sheet feeding unit 30 is detachably mounted to each main body of the sheet feeding devices 11, 12, 13 and 14, so that the sheet feeding unit 30 can be detached for maintenance and checking thereof. Fig. 5 illustrates an exemplary construction of the sheet feeding unit 30 for detachably mounting the sheet feeding unit 30 to each main body of the sheet feeding devices 11, 12, 13 and 14.
As illustrated in Fig. 5, the frame 29 of the sheet feeding unit 30 includes a front plate part 29a and a rear plate part 29b. An L-shaped mounting metal 70 is fixed to the front plate part 29a and two pins 71 and 72 are fixed to the rear plate part 29b extending in the axial direction of the feeding roller 21. A rear side plate 75 and a front side plate 76 are provided to the main body of the sheet feeding unit 30, and holes 77 and 78 are formed in the rear side plate 75 so that the pins 71 and 72 are inserted therein respectively. The hole 77 is formed in an elongated form in a horizontal direction. Screws holes 73 are formed in the mounting metal 70 for screw bolts 74, and screw holes (not shown) are formed in the front side plate 76 at positions corresponding to the screw holes 73.
The sheet feeding unit 30 is supported by the rear side plate 75 with the pins 71 and 72 inserted into the holes 77 and 78 at the rear side of each of the sheet feeding devices 11, 12, 13 and 14, and at the front side, by the front side plate 76 with the screw bolts 74 inserted into the screw holes 73 of the mounting metal 70 and the corresponding screw holes of the front side plate 76. Accordingly, when taking out the sheet feeding unit 30 from each of the sheet feeding devices 11, 12, 13 and 14, first the screw bolts 74 are removed, and then the sheet feeding unit 30 is moved in a direction indicated by arrow B, so that the sheet feeding unit 30 is swung substantially around the pin 72. After the sheet feeding unit 30 is moved to a position where the sheet feeding unit 30 does not interfere with the front side plate 76, by drawing out the sheet feeding unit 30 in a direction indicated by arrow C, the sheet feeding unit 30 can be taken out of the corresponding sheet feeding device. The hole 77 is formed in an elongated hole so that the sheet feeding unit 30 can be easily swung in the direction indicated by arrow B. The sheet feeding unit 30 can be attached to each of the sheet feeding devices 11, 12, 13 and 14 by performing the above-described procedures in the reverse order.
In the image forming apparatus of the present invention illustrated in Fig. 1, in which the sheet feeding devices 11, 12, 13 and 14 are arranged in multiple stages in a vertical direction, when a lower side sheet feeding device in the multiple stages, for example, the sheet feeding device 14, feeds a sheet, the sheet cannot be conveyed to the image forming part 2 unless each of the conveying rollers 24 of the sheet feeding devices 11, 12, and 13 located above the lower side feeding device 14 is driven. In this case, the pick-up roller 23 and the feeding roller 21 of each sheet feeding unit 30 of the sheet feeding devices 11, 12, and 13 should not preferably be driven to rotate.
In the above-described image forming apparatus of according to a preferred embodiment of the present invention, the sheet feeding units 30 of the sheet feeding devices 11, 12, 13 and 14 are independent from each other, so that when the lowermost sheet feeding device 14 feeds a sheet, all of the sheet feeding devices 11, 12, 13, and 14 are driven. At that time, the motor 31 of the sheet feeding unit 30 of the lowermost feeding device 14, which feeds the sheet, is switched in the interim from being driven to rotate in the forward direction to being driven to rotate in the reverse direction. However, the motors 31 of the sheet feeding units 30 of the other three feeding devices 11, 12, and 13 are driven to rotate in the reverse direction from the start. By thus controlling the motor 31 of each of the sheet feeding units 30 of the sheet feeding devices 11, 12, 13 and 14, a sheet fed from the lowermost sheet feeding device 14 is conveyed to the image forming part 2.
In the image forming apparatus of the present invention illustrated in Fig. 1, each of the sheet feeding devices 11, 12, 13 and 14 includes a contact/separation device to move the separation roller 22 in directions indicated by arrow D in Fig. 6 to contact and separate from the feeding roller 21. Fig. 7 is a schematic drawing illustrating an example of the contact/separation device, and Fig. 8 is a schematic drawing for explaining an operation of the contact/separation device. In Figs. 7 and 8, a pressing lever 80 presses the separation roller 22 to move toward the feeding roller 21 so that the separation roller 22 contacts the feeding roller 21 by a pulling force of a pressing spring 81. A releasing lever 90 releases the pressing force of the pressing lever 80. The pressing lever 80 is rotatably attached to the frame (not shown) of the sheet feeding unit 30 via a supporting axis 82. An upwardly-pressing part 83 which upwardly presses the separation roller 22 and a downwardly-pressing part 84 which downwardly presses the separation roller 22 are formed in the pressing lever 80. The pressing spring 81 gives to the pressing lever 80 a rotational force in the clockwise direction in Fig. 8 centering around the supporting axis 82. The upwardly-pressing part 83 contacts a roller 53a fixed to the driven axis 43 of the separation roller 22, such that the pressing lever 80 presses the separation roller 22.
The releasing lever 90 is rotatably mounted to the frame (not shown) of the sheet feeding unit 30 via a supporting axis 91 (Fig. 7), and is pressed by a releasing spring 92 to rotate around the supporting axis 91 in the counterclockwise direction in Fig. 7. A plunger 96 of a solenoid 95 is connected via a pin 97 with one'end of the releasing lever 90 so as to be rotatable . Further, as illustrated in Fig. 8, the other end of the releasing lever 90 contacts a contact part 85 formed in the pressing lever 80.
When the solenoid 95 is turned off, the releasing lever 90 presses the contact part 85 of the pressing lever 80 by an elastic force of the releasing spring 92 of the releasing lever 90, and the downwardly-pressing part 84 of the pressing lever 80 contacts the driven axis 43 of the separation roller 22. Thereby, the separation roller 22 is held in a state of being separated from the feeding roller 21 while resisting an operation of the pressing spring 81. When the solenoid 95 is turned on, the plunger 96 is pulled in the direction indicated by arrow E in Fig. 7, and the releasing lever 90 is rotated centered around the supporting axis 91 in the clockwise direction indicated by arrow F while resisting an operation of the releasing spring 92, so that the releasing lever 90 separate from the contact part 85. Thereby, the pressing lever 80 rotates in the clockwise direction by an operation of the pressing spring 81, and upwardly moves the separation roller 22 via the upwardly-pressing part 83, so that the separation roller 22 is pressed against and contacts the feeding roller 21.
As described above, in the above-described contact/separation device, the separation roller 22 is brought into contact with and separated from the feeding roller 21 by turning on/off of the solenoid 95. Therefore, with provision of the above-described contact/separation device to each of the sheet feeding devices 11, 12, 13 and 14, in each of the sheer feeding devices not feeding a sheet, even when the separation roller 22 and the conveying roller 24 are driven, by separating the separation roller 22 from the feeding roller 21, unnecessary load given to the separation roller 22 is avoided, and thereby the sheet feeding devices not feeding the sheet can be driven by a power lower than that for the sheet feeding device feeding the sheet. Specifically, when the power supplied to the stepping motor 31 of the sheet feeding unit 30 of the sheet feeding device feeding a sheet is set at, e.g., a maximum phase current of 1.3A (hereinafter, a high power), the sheet can be satisfactorily conveyed even when the stepping motor 31 of the sheet feeding unit 30 of those sheet feeding devices not feeding the sheet is switched to, e.g., a maximum phase current of 0.9A (hereinafter, a low power) , which is lower than the high power for the sheet feeding device feeding the sheet. Fig. 9 illustrates a table showing which sheet feeding devices are driven at the low power when each of the sheet feeding devices 11, 12, 13 and 14 is selected for sheet feeding. In the table of Fig. 9, the sheet feeding device marked with "H" is the one selected for sheet feeding, in which therefor the motor 31 of the sheet feeding unit 30 thereof is driven at the high power. The sheet feeding devices marked with "L" are the ones not selected for sheet feeding, in which therefore the motor 31 is driven at the lower power. The sheet feeding devices marked with "x" are the ones not driven. Thus, in the above-described image forming'apparatus according to an embodiment of the present invention, the consumption of electricity is reduced as compared when each of the motors 31 of the sheet feeding devices located above the sheet feeding device selected for sheet feeding is driven at the same high power as that for the sheet feeding device selected for sheet feeding. Further, as a lower side one of the sheet feeding devices 11, 12, 13 and 14 is selected for sheet feeding, reduction in the consumption of electricity is greater.
Fig. 10 is a schematic drawing of an example of the sheet feeding unit 30 according to another preferred embodiment of the present invention. Fig. 11 is a front view illustrating the sheet feeding devices 11, 12, 13, and 14, arranged in multiple-stages in a vertical direction, each including the sheet feeding unit 30 of Fi. 10. In Figs. 10 and 11, the same or corresponding members as in the above-described embodiment are denoted by same reference numerals. The mechanism connecting the motor 31 with the driving axis 34 of the separation roller 22 is substantially the same as in the previous embodiment. Therefore, the description thereof is omitted.
A timing pulley 50 having a gear 51 is arranged below the timing pulley 46 having the gear 47, and the timing belt 49 is spanned around three timing pulleys, the timing pulley 44, the timing pulley 46 having the gear 47, and the timing pulley 50 having the gear 51. A lower relaying gear 52 engages with the gear 51 of the timing pulley 50. A gear 54 is provided to the roller axis 45'of the conveying roller 24 so as to substantially overlay with the gear 48. The gear 54 engages with an upper relaying gear 53. Further, the lower relaying gear 52 of the sheet feeding unit 30 of, for example, the sheet feeding device 11, engages with the upper relaying gear 53 of the sheet feeding unit 30 of the sheet feeding device 12 arranged below the sheet feeding device 11, as illustrated in Fig. 11. The gear 54 is provided to the roller axis 45 of the conveying roller 24 via a one-way clutch 54a. When the gear 47 of the timing pulley 46 or the upper relaying gear 53 rotates, the one-way clutch 54a transmits each driving force so that the conveying roller 24 rotates. However, because the one-way clutch 54a does not transmit rotation of the roller axis 45 of the conveying roller 24 to the upper relaying gear 53 and the gear 47, the upper relaying gear 53 is never rotated by rotation of the conveying roller 24.
Thus, in each of the sheet feeding devices 11, 12, 13 and 14 configured as described above and arranged in multiple-stages as illustrated in Fig. 11, when the upper relaying gear 53 of the sheet feeding unit 30 of, for example, the sheet feeding device 12 , is rotated by receiving a driving force of the lower relaying gear 52 of the sheet feeding unit 30 of the sheet feeding device 11 located immediately above, the conveying roller 24 of the sheet feeding unit 30 of the sheet feeding device 12 rotates. When the gear 48 of the roller axis 45 of the conveying roller 24 rotates, the timing pulley 46 having the gear 47 engaging with the gear 48 rotates, and the timing belt 49 moves in the clockwise direction in Fig. 11. Accordingly, because the timing pulley 50 having the gear 51 rotates, the lower relaying gear 52 engaging with the gear 51 of the timing pulley 50 rotates. A driving force caused by movement of the timing belt 49 is not transmitted to the driving axis 34 of the separation roller 22, because as illustrated in Fig. 10, a one-way clutch 44a is provided to the timing pulley 44 such that the movement of the timing belt 49 in the clockwise direction is not transmitted to the driving axis 34 of the separation roller 22,
Thus, when the lower relaying gear 52 of the feeding unit 30 of the sheet feeding device 11 at the uppermost stage of the multiple stages is rotated, the conveying roller 24 of each feeding unit 30 of other sheet feeding devices below the upper sheet feeding device 11 can be rotated. Therefore, when the sheet feeding device 14 at the lowermost stage feeds a sheet, the uppermost sheet feeding device 11 and the lowermost sheet feeding device 14 are driven, and without driving of the intermediate sheet feeding devices 12 and 13, the conveying roller 24 of each sheet feeding unit 30 of the intermediate sheet feeding devices 12 and 13 are driven by receiving a driving force of the sheet feeding unit 30 of the uppermost sheet feeding device 11. Accordingly, as indicated by a table of Fig. 12, because sheet feeding can be performed by driving only the uppermost sheet feeding device 11 and one of the other sheet feeding devices 12, 13 and 14 selected for sheet feeding, the effect of reducing the power consumption increases as the number of stages of sheet feeding devices increases. The motor 31 of the feeding unit 30 of the uppermost sheet feeding device 11 rotates only in the reverse direction unless the uppermost sheet feeding device 11 is selected for sheet feeding.
In the above-described embodiment, a driving force of the motor 31 is transmitted to the feeding roller 21 and the separation roller 22 using a belt and gears so that the feeding roller 21 and the separation roller 22 are driven to rotate. However, the driving force of the motor 31 can be transmitted to the feeding roller 21 and the separation roller 22 using a series of gears. Fig. 13 illustrates an exemplary construction of the sheet feeding unit 30 in which a driving force of the motor 31 is transmitted to the feeding roller 21 and the separation roller 23 via a series of gears.
In Fig. 13, a gear 60 is provided to the output axis 32 of the motor 31, and the gear 60 engages with a gear 61 provided to the driving axis 34 of the separation roller 22 via a one-way clutch 61a. The gear 61 engages, via an idle gear 62, with a small-diameter two-step gear 63b provided to the driving axis 33 of the feeding roller 21 via a one-way clutch 63a. Further, a large-diameter two-step gear 63c engages with a gear 40 provided to the driving axis 34 via a one-way clutch 40a. In this case, the one-way clutch 61a is configured such that rotation of the gear 61 is transmitted to the driving gear 34 of the separation roller 22 when the gear 61 is rotated with rotation of the motor 31 in the reverse direction, and the rotation of the gear 61 is not transmitted to the driving gear 34 when the motor 31 rotates in the forward direction. Further, the one-way clutch 63a is configured such that rotation of the gear 61 is transmitted to the driving axis 33 of the feeding roller 21 when the gear 61 is rotated with rotation of the motor 31 in the forward direction. Furthermore, the one-way clutch 40a is configured such that driving of the gear 40 is transmitted to the driving axis 34 of the separation roller 22 when the gear 40 is driven via the two-step gears 63b and 63c.
In the sheet feeding unit 30 configured as described above, when the motor 31 rotates in the forward direction, a driving force of the motor 31 is transmitted via the gear 61, the idle gear 62 and the two-step gears 63b and 63c, so that the driving axis 33 of the feeding roller 21 is driven to rotate, and further the gear 40 engaging with the two-step gears 63b and 63c is rotated, so that the driving axis 34 of the separation roller 22 is driven to rotate. When the motor 31 rotates in the reverse direction, the driving axis 34 of the separation roller 22 is driven to rotate by the gear 61. However, the driving axis 33 of the feeding roller 21 is not driven to rotate, because the one-way clutch 63a provided at the two-step gears 63b and 63c does not transit the driving force of the motor 31 when the motor 31 rotates in the reverse direction.
In the above-described embodiment, substantially the same effect as in the previous embodiments is obtained. Further, in the above-described embodiment, the part of the sheet feeding unit 30 downstream of the driving axis 34 of the separation roller 22 in the direction in which a driving force of the motor 31 is transmitted is substantially the same as that in the previous embodiments, and therefore the description thereof is omitted.
Numerous additional modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the present invention may be practiced otherwise than as specifically described herein.
The present application claims priority and contains subject matter related to Japanese Patent Applications No. 2000-400698, and No. 2001- 366526 filed in the Japanese Patent Office on December 28, 2000 and November 30 2001, respectively, and the entire contents of which are hereby incorporated by reference.

Claims

A sheet feeding device comprising:

a sheet tray configured to accommodate stacked sheets; and

a feeding unit configured to feed the stacked sheets in the sheet tray one by one, the sheet feeding unit including,
a feeding roller configured to be driven to rotate in a sheet feeding direction in which each of the sheets is fed,
a separation roller configured to be pressed against the feeding roller when feeding each of the sheets and to be driven to rotate, via a torque limiter, in a direction opposite the sheet feeding direction, the separation roller being rotated by rotation of the feeding roller in the sheet feeding direction when a single sheet of the stacked sheets is sandwiched between the feeding roller and the separation roller,
a conveying member arranged downstream of the feeding roller in the sheet feeding direction; and
a driving source for driving the feeding roller, the separation roller, and the conveying member, and
a driving force transmission mechanism configured to transmit a driving force of the driving source to each of the feeding roller, the separation roller and the conveying member such that the separation roller and the conveying member are driven in conjunction with each other.
The sheet feeding device of Claim 1,
wherein the driving source includes a reversible motor configured to be switched between being driven to rotate in first and second directions.
The sheet feeding device of Claim 2,
wherein the driving transmission mechanism is configured to transmit the driving force of the motor such that the feeding roller, the separation roller, and the conveying member are driven when the driving source is driven to rotate in the first direction, and such that the feeding roller is not driven and the separation roller and the conveying member are driven in conjunction with each other when the driving source is driven to rotate in the second direction.
The sheet feeding device of Claim 2 or 3
wherein the separation roller and the conveying member are configured to be continuously driven in conjunction with each other by the driving source from when each sheet starts to be fed by the feeding roller until the sheet passes the conveying member.
The sheet feeding device of Claim 2,3 or 4
wherein the driving source is switched from being driven to rotate in the first direction to being driven to rotate in the second direction while the sheet is being sandwiched between the feeding roller and the separation roller.
The sheet feeding device of Claim 2, 3, 4 or 5
wherein the driving force transmission mechanism includes driving force transmission members and mechanical one-way clutches.
The sheet feeding device of Claim 6,
wherein the driving force transmission members include gears and a belt.
The sheet feeding device of Claim 7,
wherein when the driving source is driven to rotate in the first direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via the belt and the gears, and when the driving source is driven to rotate in the second direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via the belt.
The sheet feeding device of Claim 6,
wherein the driving force transmission members include a series of gears.
The sheet feeding device of Claim9,
wherein when the driving source is driven to rotate in the first direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via a first portion of the series of gears, and when the driving source is driven to rotate in the second direction, the driving force transmission mechanism transmits the driving force of the driving source to the separation roller via a second portion of the series of gears, the first portion of the series of gears being greater in number than the second portion of the series of gears by an odd number.
The sheet feeding device of Claim 2,
wherein the driving force transmission mechanism includes a first rotation transmission route configured to transmit the driving force of the driving source when the driving source is driven to rotate in the first direction and a second rotation transmission route configured to transmit the driving force of the driving source when the driving source is driven to rotate in the second direction.
The sheet feeding device of Claim 11,
wherein the driving force transmission mechanism includes a belt and gears, and
wherein the first rotation transmission route is configured to transmit the driving force of the driving source to the feeding roller via the belt and then from the feeding roller to the reverse roller via the gears, and the second rotation transmission route is configured to transmit the driving force of the driving source to the separation roller via the belt.
The sheet feeding device of Claim 11,
wherein the driving force transmission mechanism includes a series of gears, and
wherein the first rotation transmission route is configured to transmit the driving force of the driving source to the separation roller via a first portion of the series of gears and the second rotation transmission route is configured to transmit the driving force of the driving source to the separation roller via a second portion of the series of gears, the first portion of the series of gears being greater in number than the second portion of the series of gears by an odd number.
The sheet feeding device of any one of the preceding claims,
wherein the feeding unit is detachable from the sheet feeding device.
An image forming apparatus, comprising:

an image forming unit configured to form a toner image on a photoconductor; and

a sheet feeding device according to any one of the preceding claims configured to accommodate stacked sheets and to feed the stacked sheets one by one toward the image forming unit so that the toner image is transferred onto each sheet at the image forming unit
An image forming apparatus, comprising:

an image forming unit configured to form a toner image on a photoconductor; and

a plurality of sheet feeding devices according to any one of claims 1 to 14 configured to accommodate stacked sheets and to feed the stacked sheets

one by one toward the image forming unit so that the toner image is transferred onto each sheet at the image forming unit
The image forming apparatus of Claim 16,
wherein the plurality of sheet feeding devices are arranged in multiple stages in a vertical direction in parallel with each other, and
wherein the sheet feeding units of the plurality of sheet feeding devices are individually driven such that each sheet fed from one of the plurality of sheet feeding devices is fed toward the image forming unit via the conveying member of each of other sheet feeding devices of the plurality of sheet feeding devices located above the sheet feeding device from which the sheet has been fed.
The image forming apparatus of Claim 17,
wherein the sheet feeding units of any neighboring sheet feeding devices of the plurality of sheet feeding devices are connected with each other such that the driving force of the driving source of the feeding unit of the sheet feeding device of the neighboring sheet feeding devices, located at a lower side, is not transmitted to the feeding unit of the sheet feeding device of the neighboring feeding devices, located at an upper side, and the driving force of the driving source of the feeding unit of the sheet feeding device of the neighboring sheet feeding devices, located at the upper side, is transmitted to the sheet feeding unit of the sheet feeding device of the neighboring sheet feeding devices, located at the lower side.
The image forming apparatus of Claim 18,
wherein the separation roller and the conveying member of the feeding unit of an uppermost sheet feeding device of the plurality of sheet feeding devices and the separation roller and the conveying member of the feeding unit of the sheet feeding device of the plurality of sheet feeding devices, feeding the sheet, are respectively driven in conjunction with each other, and the separation roller and the conveying member of each of the sheet feeding units of other sheet feeding devices of the plurality of sheet feeding devices, not feeding the sheet, are not driven in conjunction with each other and only the conveying member is driven.
The image forming apparatus of Claim 17, 18 or 19
wherein the driving source of the sheet feeding unit of the sheet feeding device of the plurality of sheet feeding devices, feeding the sheet, is driven by a predetermined power, and the driving source of the sheet feeding unit of each of other sheet feeding devices located above the sheet feeding device feeding the sheet is driven at a power smaller than the predetermined power.
The image forming apparatus of Claim 20,
wherein the driving source of the sheet feeding unit of each of the other sheet feeding devices located below the sheet feeding device feeding the sheet is not driven.
The image forming apparatus of claim 20 or 21,
wherein each of the sheet feeding devices includes a contact/separation device configured to bring the separation roller into contact with and to separate the separation roller from the feeding roller, and
wherein the contact/separation device is configured to separate the separation roller from the feeding roller except when the sheet feeding device feeds each of the stacked sheets.
A sheet feeding device comprising:

means for accommodating stacked sheets; and

a feeding unit configured to feed the stacked sheets in the sheet accommodating means one by one, the sheet feeding unit including,
a feeding roller configured to be driven to rotate in a sheet feeding direction in which each of the stacked sheets is fed,
a separation roller configured to be pressed against the feeding roller when feeding each of the stacked sheets and to be driven to rotate, via a torque limiter, in a direction opposite the sheet feeding direction, the separation roller being rotated by rotation of the feeding roller in the sheet feeding direction when a single sheet of the stacked sheets is sandwiched between the feeding roller and the separation roller,
means for conveying the sheet, arranged downstream of the feeding roller in the sheet feeding direction; and
means for driving the feeding roller, the separation roller, and the conveying means, and
means for transmitting a driving force of the driving means to each of the feeding roller, the separation roller and the conveying means such that the separation roller and the conveying means are driven in conjunction with each other.
An image forming apparatus, comprising:

means for forming a toner image on a photoconductor; and

a sheet feeding device including means for accommodating stacked sheets and a feeding unit configured to feed the stacked sheets in the sheet accommodating means one by one toward the image forming means so that the toner image is transferred onto each sheet at the image forming means, the sheet feeding unit including,
a feeding roller configured to be driven to rotate in a sheet feeding direction in which each of the stacked sheets is fed,
a separation roller configured to be pressed against the feeding roller when feeding each of the stacked sheets and to be driven to rotate, via a torque limiter, in a direction opposite the sheet feeding direction, the separation roller being rotated by rotation of the feeding roller in the sheet feeding direction when a single sheet of the stacked sheets is sandwiched between the feeding roller and the separation roller,
means for conveying the sheet, arranged downstream of the feeding roller in the sheet feeding direction; and
means for driving the feeding roller, the separation roller, and the conveying means, and
means for transmitting a driving force of the driving means to the feeding roller, the separation roller and the conveying means such that the separation roller and the conveying means are driven in conjunction with each other.
An image forming apparatus, comprising:

means for forming a toner image on a photoconductor; and

a plurality of sheet feeding devices , each including means for accommodating stacked sheets and a feeding unit configured to feed the stacked sheets in the sheet accommodating means one by one toward the image forming means so that the toner image is transferred onto each sheet at the image forming means, the sheet feeding unit including,
a feeding roller configured to be driven to rotate in a sheet feeding direction in which each of the stacked sheets is fed,
a separation roller configured to be pressed against the feeding roller when feeding each of the stacked sheets and to be driven to rotate, via a torque limiter, in a direction opposite the sheet feeding direction, the separation roller being rotated by rotation of the feeding roller in the sheet feeding direction when a single sheet of the stacked sheets is sandwiched between the feeding roller and the separation roller,
means for conveying the sheet, arranged downstream of the feeding roller in the sheet feeding direction; and
means for driving the feeding roller, the separation roller, and the conveying means, and
means for transmitting a driving force of the driving means to each of the feeding roller, the separation roller and
the conveying means such that the separation roller and the conveying means are driven in conjunction with each other.
A method of feeding stacked sheets one by one in a sheet feeding device having a feeding roller, a separation roller and a conveying member, comprising:

driving a motor to rotate in a first direction and transmitting a driving force of the motor with a driving force transmitting mechanism to the feeding roller, the separation roller and the conveying member such that the feeding roller is driven to rotate in a sheet feeding direction, the separation roller is driven to rotate in a direction opposite the sheet feeding direction, and the conveying member is driven to rotate in the sheet feeding direction; and

driving the motor to rotate in a second direction and transmitting the driving force of the motor to the feeding roller, the separation roller and the conveying member such that the feeding roller is stopped to be driven, and the separation roller and the conveying roller are driven to rotate in respective directions in conjunction with each other.